Audio signal decoder, audio signal encoder, method for providing an upmix signal representation, method for providing a downmix signal representation, computer program and bitstream using a common inter-object-correlation parameter value

ABSTRACT

An audio signal decoder for providing an upmix signal representation on the basis of a downmix signal representation and an object-related parametric information and in dependence on a rendering information has an object parameter determinator. The object parameter determinator is configured to obtain inter-object-correlation values for a plurality of pairs of audio objects. The object parameter determinator is configured to evaluate a bitstream signaling parameter in order to decide whether to evaluate individual inter-object-correlation bitstream parameter values to obtain inter-object-correlation values for a plurality of pairs of related audio objects, or to obtain inter-object-correlation values for a plurality of pairs of related audio objects using a common inter-object-correlation bitstream parameter value. The audio signal decoder also has a signal processor configured to obtain the upmix signal representation on the basis of the downmix signal representation and using the inter-object-correlation values for a plurality of pairs of related objects and the rendering information.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of copending InternationalApplication No. PCT/EP2010/064379, filed Sep. 28, 2010, which isincorporated herein by reference in its entirety, and additionallyclaims priority from U.S. Application No. U.S. 61/246,681, filed Sep.29, 2009, U.S. 61/369,505, filed Jul. 30, 2010 and European ApplicationNo. EP 10171406.1, filed Jul. 30, 2010, all of which are incorporatedherein by reference in their entirety.

Embodiments according to the invention are related to an audio signaldecoder for providing an upmix signal representation on the basis of adownmix signal representation and an object-related parametricinformation and in dependence on a rendering information.

Other embodiments according to the invention relate to an audio signalencoder for providing a bitstream representation on the basis of aplurality of audio object signals.

Other embodiments according to the invention relate to a method forproviding an upmix signal representation on the basis of a downmixsignal representation and an object-related parametric information andin dependence on a rendering information.

Other embodiments according to the invention relate to a method forproviding a bitstream representation on the basis of a plurality ofaudio object signals.

Other embodiments according to the invention are related to a computerprogram for performing said methods.

Other embodiments according to the invention are related to a bitstreamrepresenting a multi-channel audio signal.

BACKGROUND OF THE INVENTION

In the art of audio processing, audio transmission and audio storage,there is an increasing desire to handle multi-channel contents in orderto improve the hearing impression. Usage of multi-channel audio contentbrings along significant improvements for the user. For example, a3-dimensional hearing impression can be obtained, which brings along animproved user satisfaction in entertainment applications. However,multi-channel audio contents are also useful in professionalenvironments, for example in telephone conferencing applications,because the speaker intelligibility can be improved by using amulti-channel audio playback.

However, it is also desirable to have a good tradeoff between audioquality and bitrate requirements in order to avoid an excessive resourceload caused by multi-channel applications.

Recently, parametric techniques for the bitrate-efficient transmissionand/or storage of audio scenes containing multiple audio objects havebeen proposed, for example, Binaural Cue Coding (Type I) (see, forexample reference [BCC]), Joint Source Coding (see, for example,reference [JSC]), and MPEG Spatial Audio Object Coding (SAOC) (see, forexample, references [SAOC1], [SAOC2] and non-prepublished reference[SAOC]).

These techniques aim at perceptually reconstructing the desired outputaudio scene rather than a waveform match.

FIG. 8 shows a system overview of such a system (here: MPEG SAOC). Inaddition, FIG. 9a shows a system overview of such a system (here: MPEGSAOC).

The MPEG SAOC system 800 shown in FIG. 8 comprises an SAOC encoder 810and an SAOC decoder 820. The SAOC encoder 810 receives a plurality ofobject signals x₁ to x_(N), which may be represented, for example, astime-domain signals or as time-frequency-domain signals (for example, inthe form of a set of transform coefficients of a Fourier-type transform,or in the form of QMF subband signals). The SAOC encoder 810 typicallyalso receives downmix coefficients d₁ to d_(N), which are associatedwith the object signals x₁ to x_(N). Separate sets of downmixcoefficients may be available for each channel of the downmix signal.The SAOC encoder 810 is typically configured to obtain a channel of thedownmix signal by combining the object signals x₁ to x_(N) in accordancewith the associated downmix coefficients d₁ to d_(N). Typically, thereare less downmix channels than object signals x₁ to x_(N). In order toallow (at least approximately) for a separation (or separate treatment)of the object signals at the side of the SAOC decoder 820, the SAOCencoder 810 provides both the one or more downmix signals (designated asdownmix channels) 812 and a side information 814. The side information814 describes characteristics of the object signals x₁ to x_(N), inorder to allow for a decoder-sided object-specific processing.

The SAOC decoder 820 is configured to receive both the one or moredownmix signals 812 and the side information 814. Also, the SAOC decoder820 is typically configured to receive a user interaction informationand/or a user control information 822, which describes a desiredrendering setup. For example, the user interaction information/usercontrol information 822 may describe a speaker setup and the desiredspatial placement of the objects, which provide the object signals x₁ tox_(N).

The SAOC decoder 820 is configured to provide, for example, a pluralityof decoded upmix channel signals ŷ₁ to ŷ_(M). The upmix channel signalsmay for example be associated with individual speakers of amulti-speaker rendering arrangement. The SAOC decoder 820 may, forexample, comprise an object separator 820 a, which is configured toreconstruct, at least approximately, the object signals x₁ to x_(N) onthe basis of the one or more downmix signals 812 and the sideinformation 814, thereby obtaining reconstructed object signals 820 b.However, the reconstructed object signals 820 b may deviate somewhatfrom the original object signals x₁ to x_(N), for example, because theside information 814 is not quite sufficient for a perfectreconstruction due to the bitrate constraints. The SAOC decoder 820 mayfurther comprise a mixer 820 c, which may be configured to receive thereconstructed object signals 820 b and the user interactioninformation/user control information 822, and to provide, on the basisthereof, the upmix channel signals ŷ₁ to ŷ_(M). The mixer 820 may beconfigured to use the user interaction information/user controlinformation 822 to determine the contribution of the individualreconstructed object signals 820 b to the upmix channel signals ŷ₁ toŷ_(M). The user interaction information/user control information 822may, for example, comprise rendering parameters (also designated asrendering coefficients), which determine the contribution of theindividual reconstructed object signals 822 to the upmix channel signalsŷ₁ to ŷ_(M).

However, it should be noted that in many embodiments, the objectseparation, which is indicated by the object separator 820 a in FIG. 8,and the mixing, which is indicated by the mixer 820 c in FIG. 8, areperformed in single step. For this purpose, overall parameters may becomputed which describe a direct mapping of the one or more downmixsignals 812 onto the upmix channel signals ŷ₁ to ŷ_(M). These parametersmay be computed on the basis of the side information and the userinteraction information/user control information 820.

Taking reference now to FIGS. 9a, 9b and 9c , different apparatus forobtaining an upmix signal representation on the basis of a downmixsignal representation and object-related side information will bedescribed. FIG. 9a shows a block schematic diagram of a MPEG SAOC system900 comprising an SAOC decoder 920. The SAOC decoder 920 comprises, asseparate functional blocks, an object decoder 922 and a mixer/renderer926. The object decoder 922 provides a plurality of reconstructed objectsignals 924 in dependence on the downmix signal representation (forexample, in the form of one or more downmix signals represented in thetime domain or in the time-frequency-domain) and object-related sideinformation (for example, in the form of object meta data). Themixer/renderer 924 receives the reconstructed object signals 924associated with a plurality of N objects and provides, on the basisthereof, one or more upmix channel signals 928. In the SAOC decoder 920,the extraction of the object signals 924 is performed separately fromthe mixing/rendering, which allows for a separation of the objectdecoding functionality from the mixing/rendering functionality butbrings along a relatively high computational complexity.

Taking reference now to FIG. 9b , another MPEG SAOC system 930 will bebriefly discussed, which comprises an SAOC decoder 950. The SAOC decoder950 provides a plurality of upmix channel signals 958 in dependence on adownmix signal representation (for example, in the form of one or moredownmix signals) and an object-related side information (for example, inthe form of object meta data). The SAOC decoder 950 comprises a combinedobject decoder and mixer/renderer, which is configured to obtain theupmix channel signals 958 in a joint mixing process without a separationof the object decoding and the mixing/rendering, wherein the parametersfor said joint upmix process are dependent both on the object-relatedside information and the rendering information. The joint upmix processdepends also on the downmix information, which is considered to be partof the object-related side information.

To summarize the above, the provision of the upmix channel signals 928,958 can be performed in a one-step process or a two-step process.

Taking reference now to FIG. 9c , an MPEG SAOC system 960 will bedescribed. The SAOC system 960 comprises an SAOC to MPEG Surroundtranscoder 980, rather than an SAOC decoder.

The SAOC to MPEG Surround transcoder comprises a side informationtranscoder 982, which is configured to receive the object-related sideinformation (for example, in the form of object meta data) and,optionally, information on the one or more downmix signals and therendering information. The side information transcoder is alsoconfigured to provide an MPEG Surround side information (for example, inthe form of an MPEG Surround bitstream) on the basis of a received data.Accordingly, the side information transcoder 982 is configured totransform an object-related (parametric) side information, which isrelieved from the object encoder, into a channel-related (parametric)side information, taking into consideration the rendering informationand, optionally, the information about the content of the one or moredownmix signals.

Optionally, the SAOC to MPEG Surround transcoder 980 may be configuredto manipulate the one or more downmix signals, described, for example,by the downmix signal representation, to obtain a manipulated downmixsignal representation 988. However, the downmix signal manipulator 986may be omitted, such that the output downmix signal representation 988of the SAOC to MPEG Surround transcoder 980 is identical to the inputdownmix signal representation of the SAOC to MPEG Surround transcoder.The downmix signal manipulator 986 may, for example, be used if thechannel-related MPEG Surround side information 984 would not allow toprovide a desired hearing impression on the basis of the input downmixsignal representation of the SAOC to MPEG Surround transcoder 980, whichmay be the case in some rendering constellations.

Accordingly, the SAOC to MPEG Surround transcoder 980 provides thedownmix signal representation 988 and the MPEG Surround bitstream 984such that a plurality of upmix channel signals, which represent theaudio objects in accordance with the rendering information input to theSAOC to MPEG Surround transcoder 980 can be generated using an MPEGSurround decoder which receives the MPEG Surround bitstream 984 and thedownmix signal representation 988.

To summarize the above, different concepts for decoding SAOC-encodedaudio signals can be used. In some cases, a SAOC decoder is used, whichprovides upmix channel signals (for example, upmix channel signals 928,958) in dependence on the downmix signal representation and theobject-related parametric side information. Examples for this conceptcan be seen in FIGS. 9a and 9b . Alternatively, the SAOC-encoded audioinformation may be transcoded to obtain a downmix signal representation(for example, a downmix signal representation 988) and a channel-relatedside information (for example, the channel-related MPEG Surroundbitstream 984), which can be used by an MPEG Surround decoder to providethe desired upmix channel signals.

In the MPEG SAOC system 800, a system overview of which is given in FIG.8, and also in the MPEG SAOC system 900, a system overview of which isgiven in FIG. 9, the general processing is carried out in a frequencyselective way and can be described as follows within each frequencyband:

-   -   N input audio object signals x₁ to x_(N) are downmixed as part        of the SAOC encoder processing. For a mono downmix, the downmix        coefficients are denoted by d₁ to d_(N). In addition, the SAOC        encoder 810, 910 extracts side information 814 describing the        characteristics of the input audio objects. An important part of        this side information consists of relations of the object powers        and correlations with respect to each other, i.e., object-level        differences (OLDs) in inter-object-correlations (IOCs).    -   Downmix signal (or signals) 812, 912 and side information 814,        914 are transmitted and/or stored. To this end, the downmix        audio signal may be compressed using well-known perceptual audio        coders such as MPEG-1 Layer II or III (also known as “.mp3”),        MPEG Advanced Audio Coding (AAC), or any other audio coder.    -   On the receiving end, the SAOC decoder 820, 920 conceptually        tries to restore the original object signals (“object        separation”) using the transmitted side information 814, 914        (and, naturally, the one or more downmix signals 812, 912).        These approximated object signals (also designated as        reconstructed object signals 820 b, 924) are then mixed into a        target scene represented by M audio output channels (which may,        for example, be represented by the upmix channel signals ŷ₁ to        ŷ_(M), 928) using a rendering matrix. For a mono output, the        rendering matrix coefficients are given by r₁ to r_(N)    -   Effectively, the separation of the object signals is rarely        executed (or even never executed), since both the separation        step (indicated by the object separator 820 a, 922) and the        mixing step (indicated by the mixer 820 c, 926) are combined        into a single transcoding step, which often results in an        enormous reduction in computational complexity.

It has been found that such a scheme is tremendously efficient, both interms of transmission bitrate (it is only needed to transmit a fewdownmix channels plus some side information instead of N object audiosignals) and computational complexity (the processing complexity relatesmainly to the number of output channels rather than the number of audioobjects). Further advantages for the user on the receiving end includethe freedom of choosing a rendering setup of his/her choice (mono,stereo, surround, virtualized headphone playback, and so on) and thefeature of user interactivity: the rendering matrix, and thus the outputscene, can be set and changed interactively by the user according towill, personal preference or other criteria. For example, it is possibleto locate the talkers from one group together in one spatial area tomaximize discrimination from other remaining talkers. This interactivityis achieved by providing a decoder user interface:

For each transmitted sound object, its relative level and (for non-monorendering) spatial position of rendering can be adjusted. This mayhappen in real-time as the user changes the position of the associatedgraphical user interface (GUI) sliders (for example: object-level=+5 dB,object position=−30 deg).

In the following, a short reference will be given to techniques, whichhave been applied previously in the field of channel-based audio coding.

U.S. Ser. No. 11/032,689 describes a process for combining several cuevalues into a single transmitted one in order to save side information.

This technique is also applied to “multi-channel hierarchal audio codingwith compact side information” in U.S. 60/671,544.

However, it has been found that the object-related parametricinformation, which is used for an encoding of a multi-channel audiocontent, comprises a comparatively high bit rate in some cases.

SUMMARY

According to an embodiment, an audio signal decoder for providing anupmix signal representation on the basis of a downmix signalrepresentation and an object-related parametric information, anddepending on a rendering information, may have an object parameterdeterminator configured to acquire inter-object-correlation values for aplurality of pairs of audio objects, wherein the object parameterdeterminator is configured to evaluate a bitstream signaling parameterin order to decide whether to evaluate individualinter-object-correlation bitstream parameter values, to acquireinter-object-correlation values for a plurality of pairs of relatedaudio objects, or to acquire inter-object-correlation values for aplurality of pairs of related audio objects using a commoninter-object-correlation bitstream parameter value; and a signalprocessor configured to acquire the upmix signal representation on thebasis of the downmix signal representation and using theinter-object-correlation values for a plurality of pairs of relatedaudio objects and the rendering information; wherein the object-relatedparametric information has the bitstream signaling parameter and theindividual inter-object-correlation bitstream parameter values or thecommon inter-object-correlation bitstream parameter value; wherein theobject parameter determinator is configured to evaluate anobject-relationship-information, describing whether two audio objectsare related to each other; and wherein the object parameter determinatoris configured to selectively acquire inter-object-correlation values forpairs of audio objects, for which the object-relationship-informationindicates a relationship, using the common inter-object-correlationbitstream parameter value and to set inter-object-correlation values forpairs of audio objects, for which the object-relationship informationindicates no relationship, to a predefined value.

According to another embodiment, an audio signal encoder for providing abitstream representation on the basis of a plurality of audio objectsignals may have a downmixer configured to provide a downmix signal onthe basis of the audio object signals and in dependence on downmixparameters describing contributions of the audio object signals to oneor more channels of the downmix signal; and a parameter providerconfigured to provide a common inter-object-correlation bitstreamparameter value associated with a plurality of pairs of related audioobject signals, and to also provide a bitstream signaling parameterindicating that the common inter-object-correlation bitstream parametervalue is provided instead of a plurality of individualinter-object-correlation bitstream parameter values; wherein theparameter provider is configured to also provide an object relationshipinformation describing whether two audio objects are related to eachother; and a bitstream formatter configured to provide a bitstreamhaving a representation of the downmix signal, a representation of thecommon inter-object-correlation bitstream parameter value and thebitstream signaling parameter.

According to another embodiment, a method for providing an upmix signalrepresentation on the basis of a downmix signal representation and anobject-related parametric information and in dependence on a renderinginformation may have the steps of acquiring inter-object-correlationvalues for a plurality of pairs of audio objects, wherein a bitstreamsignaling parameter is evaluated in order to decide whether to evaluateindividual inter-object-correlation bitstream parameter values, toacquire inter-object-correlation values for a plurality of pairs ofrelated audio objects, or to acquire inter-object-correlation values fora plurality of pairs of related audio objects using a commoninter-object-correlation bitstream parameter value; and acquiring theupmix signal representation on the basis of the downmix signalrepresentation and using the inter-object-correlation values for aplurality of pairs of related audio objects and the renderinginformation; wherein an object-relationship information, describingwhether two audio objects are related to each other, is evaluated, andwherein the inter-object-correlation values are selectively acquired forpairs of audio objects, for which the object relationship-informationindicates a relationship, using the common inter-object-correlationbitstream parameter value, and wherein the inter-object-correlationvalues are set to a predefined value for pairs of audio objects, forwhich the object-relationship information indicates no relationship; andwherein the object-related parametric information has the bitstreamsignaling parameter and the individual inter-object-correlationbitstream parameter values or the common inter-object-correlationbitstream parameter value.

According to another embodiment, a method for providing a bitstreamrepresentation on the basis of a plurality of audio object signals mayhave the steps of providing a downmix signal on the basis of the audioobject signals and in dependence on downmix parameters describingcontributions of the audio object signals to the one or more channels ofthe downmix signal; and providing a common inter-object-correlationbitstream parameter value associated with a plurality of pairs ofrelated audio object signals; and providing a bitstream signalingparameter indicating that the common inter-object-correlation bitstreamparameter value is provided instead of a plurality of individualinter-object-correlation bitstream parameter values; and providing anobject-relationship information describing whether two audio objects arerelated to each other, providing a bitstream having a representation ofthe downmix signal, a representation of the commoninter-object-correlation bitstream parameter value and the bitstreamsignaling parameter.

According to another embodiment, a computer program may perform one ofthe above mentioned methods, when the computer program runs on acomputer.

According to another embodiment, a bitstream representing amulti-channel audio signal may have a representation of a downmix signalcombining audio signals of a plurality of audio objects; and anobject-related parametric side information describing characteristics ofthe audio objects, wherein the object-related parametric sideinformation has a bitstream signaling parameter indicating whether thebitstream has individual inter-object-correlation bitstream parametervalues or a common inter-object-correlation bitstream parameter value,and an object-relationship information describing whether two audioobjects are related to each other.

According to another embodiment, an audio signal decoder for providingan upmix signal representation on the basis of a downmix signalrepresentation and an object-related parametric information, anddepending on a rendering information, may have an object parameterdeterminator configured to acquire inter-object-correlation values for aplurality of pairs of audio objects, wherein the object parameterdeterminator is configured to evaluate a bitstream signaling parameterin order to decide whether to evaluate individualinter-object-correlation bitstream parameter values, to acquireinter-object-correlation values for a plurality of pairs of relatedaudio objects, or to acquire inter-object-correlation values for aplurality of pairs of related audio objects using a commoninter-object-correlation bitstream parameter value; and a signalprocessor configured to acquire the upmix signal representation on thebasis of the downmix signal representation and using theinter-object-correlation values for a plurality of pairs of relatedaudio objects and the rendering information; wherein the audio signaldecoder is configured to combine an inter-object-correlation valueIOC_(i,j) associated with a pair of related audio objects with an objectlevel difference value OLD_(i) describing an object level of a firstaudio object of the pair of related audio objects and with an objectlevel difference value OLD_(j) describing an object level of a secondaudio object of the pair of related audio objects, to acquire acovariance value e_(i,j) associated with the pair of related audioobjects; wherein the audio decoder is configured to acquire an elemente_(i,j) of a covariance matrix according to e_(i,j)=√{square root over(OLD_(i)OLD_(j))}IOC_(i,j).

According to another embodiment, a method for providing an upmix signalrepresentation on the basis of a downmix signal representation and anobject-related parametric information and in dependence on a renderinginformation, may have the steps of acquiring inter-object-correlationvalues for a plurality of pairs of audio objects, wherein a bitstreamsignaling parameter is evaluated in order to decide whether to evaluateindividual inter-object-correlation bitstream parameter values, toacquire inter-object-correlation values for a plurality of pairs ofrelated audio objects, or to acquire inter-object-correlation values fora plurality of pairs of related audio objects using a commoninter-object-correlation bitstream parameter value; and acquiring theupmix signal representation on the basis of the downmix signalrepresentation and using the inter-object-correlation values for aplurality of pairs of related audio objects and the renderinginformation; wherein an inter-object-correlation value IOC_(i,j)associated with a pair of related audio objects is combined with anobject level difference value OLD_(i) describing an object level of afirst audio object of the pair of related audio objects and with anobject level difference value OLD_(j) describing an object level of asecond audio object of the pair of related audio objects, to acquire acovariance value e_(i,j) associated with the pair of related audioobjects; wherein an element e_(i,j) of a covariance matrix is acquiredaccording to e_(i,j)=√{square root over (OLD_(i)OLD_(j))}IOC_(i,j).

According to another embodiment, a computer program may perform theabove-mentioned method, when the computer program runs on a computer.

An embodiment according to the invention creates an audio signal decoderfor providing an upmix signal representation on the basis of a downmixsignal representation and an object-related parametric information andin dependence on a rendering information. The apparatus comprises anobject-parameter determinator configured to obtaininter-object-correlation values for a plurality of pairs of audioobjects. The object-parameter determinator is configured to evaluate abitstream signalling parameter in order to decide whether to evaluateindividual inter-object-correlation bitstream parameter values to obtaininter-object-correlation values for a plurality of pairs of relatedaudio objects or to obtain inter-object-correlation values for aplurality of pairs of related audio objects using a commoninter-object-correlation bitstream parameter value. The audio signaldecoder also comprises a signal processor configured to obtain the upmixsignal representation on the basis of the downmix signal representationand using the inter-object-correlation values for a plurality of pairsof related audio objects and the rendering information.

This audio signal decoder is based on the key idea that a bit rateneeded for encoding inter-object-correlation values can be excessivelyhigh in some cases in which correlations between many pairs of audioobjects need to be considered in order to obtain a good hearingimpression, and that a bit rate needed to encode theinter-object-correlation values can be significant reduced in such casesby using a common inter-object-correlation bitstream parameter valuerather than individual inter-object-correlation bitstream parametervalues without significantly compromising the hearing impression.

It has been found that in situations in which there are notableinter-object-correlations between many pairs of audio objects, whichshould be considered in order to obtain a good hearing impression, aconsideration of the inter-object-correlations would normally result ina high bitrate requirement for the inter-object-correlation bitstreamparameter values. However, it has been found that in such situations, inwhich there is a non-negligible inter-object-correlation between manypairs of audio objects, a good hearing impression can be achieved bymerely encoding a single common inter-object-correlation bitstreamparameter value, and by deriving the inter-object-correlation values fora plurality of pairs of related audio objects from such a commoninter-object-correlation bitstream parameter value. Accordingly, thecorrelation between many audio objects can be considered with sufficientaccuracy in most cases, while keeping the effort for the transmission ofthe inter-object-correlation bitstream parameter value sufficientlysmall.

Therefore, the above-discussed concept results in a small bit ratedemand for the object-related side information in some acousticenvironments in which there is a non-negligible inter-object-correlationbetween many different audio object signals, while still achieving asufficiently good hearing impression.

In an embodiment, the object-parameter determinator is configured to setthe inter-object-correlation value for all pairs of different relatedaudio objects to a common value defined by the commoninter-object-correlation bitstream parameter value. It has been foundthat this simple solution brings along a sufficiently good hearingimpression in many relevant situations.

In an embodiment, the object-parameter determinator is configured toevaluate an object-relationship information describing whether twoobjects are related to each other or not. The object-parameterdeterminator is further configured to selectively obtaininter-object-correlation values for pairs of audio objects for which theobject-relationship information indicates a relationship using thecommon inter-object-correlation bitstream parameter value, and to setinter-object-correlation values for pairs of audio objects for which theobject-relationship information indicates no relationship to apredefined value (for example, to zero). Accordingly, it can bedistinguished, with high bitrate efficiency, between related andunrelated audio objects. Therefore, an allocation of a non-zerointer-object-correlation value to pairs of audio objects, which are(approximately) unrelated, is avoided. Accordingly, a degradation of ahearing impression is avoided and a separation between suchapproximately unrelated audio objects is possible. Moreover, thesignalling of related and unrelated audio objects can be performed withvery high bitrate efficiency, because the audio object relationship istypically time-invariant over a piece of audio, such that the neededbitrate for this signalling is typically very low. Thus, the describedconcept brings along a very good trade-off between bitrate efficiencyand hearing impression.

In an embodiment, the object parameter determinator is configured toevaluate an object-relationship information comprising a one-bit flagfor each combination of different audio objects, wherein the one-bitflag associated to a given combination of different audio objectsindicates whether the audio objects of the given combination are relatedor not. Such an information can be transmitted very efficiently andresults in a significant reduction of the needed bit rate to achieve agood hearing impression.

In an embodiment, the object-parameter determinator is configured to setthe inter-object-correlation values for all pairs of different relatedaudio objects to a common value defined by the commoninter-object-correlation bitstream parameter value.

In an embodiment, the object-parameter determinator comprises abitstream parser configured to parse a bitstream representation of anaudio content to obtain the bitstream signalling parameter and theindividual inter-object-correlation bitstream parameters or the commoninter-object-correlation bitstream parameter. By using a bitstreamparser, the bitstream signalling parameter and the individualinter-object-correlation bitstream parameters or the commoninter-object-correlation bitstream parameter can be obtained with goodimplementation efficiency.

In an embodiment, the audio signal decoder is configured to combine aninter-object-correlation value associated with a pair of related audioobjects with an object-level difference parameter value describing anobject level of a first audio object of the pair of related audioobjects and with an object-level difference parameter value describingan object level of a second audio object of the pair of related audioobjects to obtain a covariance value associated with the pair of relatedaudio objects. Accordingly, it is possible to derive the covariancevalue associated to a pair of related audio objects such that thecovariance value is adapted to the pair of audio objects even though acommon inter-object-correlation parameter is used. Therefore, differentcovariance values can be obtained for different pairs of audio objects.In particular, a large number of different covariance values can beobtained using the common inter-object-correlation bitstream parametervalue.

In an embodiment, the audio signal decoder is configured to handle threeor more audio objects. In this case, the object-parameter determinatoris configured to provide inter-object-correlation values for every pairof different audio objects. It has been found that meaningful values canbe obtained using the inventive concept even if there are a relativelylarge number of audio objects, which are all related to each other.Obtaining inter-object-correlation values from many combinations ofaudio objects is particularly helpful when encoding and decoding audioobject signals using an object-related parametric side information.

In an embodiment, the object-parameter determinator is configured toevaluate the bitstream signalling parameter, which is included in aconfiguration bitstream portion, in order to decide whether to evaluateindividual inter-object-correlation bitstream parameter values to obtaininter-object-correlation values for a plurality of pairs of relatedaudio objects or to obtain inter-object-correlation values for aplurality of pairs of related audio objects using a commoninter-object-correlation bitstream parameter value. In this embodiment,the object-parameter determinator is configured to evaluate an objectrelationship information, which is included in the configurationbitstream portion, to determine whether the audio objects are related.In addition, the object-parameter determinator is configured to evaluatea common inter-object-correlation bitstream parameter value, which isincluded in a frame data bitstream portion, for every frame of the audiocontent if it is decided to obtain inter-object-correlation values for aplurality of pairs of related audio objects using a commoninter-object-correlation bitstream parameter value. Accordingly, a highbitrate efficiency is obtained, because the comparatively large objectrelationship information is evaluated only once per audio piece (whichis defined by the presence of a configuration bitstream portion), whilethe comparatively small common inter-object-correlation bitstreamparameter value is evaluated for every frame of the audio piece, i.e.multiple times per audio piece. This reflects the finding that therelationship between audio objects typically does not change within anaudio piece or only changes very rarely. Accordingly, a good hearingimpression can be obtained at a reasonably low bitrate.

Alternatively, however, the usage of a common inter-object-correlationbitstream parameter value could be signaled in a frame data bitstreamportion, which would, for example, allow for a flexible adaptation tovarying audio contents.

An embodiment according to the invention creates an audio signal encoderfor providing a bitstream representation on the basis of a plurality ofaudio object signals. The audio signal encoder comprises a downmixerconfigured to provide a downmix signal on the basis of the audio objectsignals and in dependence on downmix parameters describing contributionsof the audio object signals to be one or more channels of the downmixsignal. The audio signal encoder also comprises a parameter providerconfigured to provide a common inter-object-correlation bitstreamparameter value associated with a plurality of pairs of related audioobject signals and to also provide a bitstream signalling parameterindicating that the common inter-object-correlation bitstream parametervalue is provided instead of a plurality of individualinter-object-correlation bitstream parameters. The audio signal encoderalso comprises a bitstream formatter configured to provide a bitstreamcomprising a representation of the downmix signal, a representation ofthe common inter-object-correlation bitstream parameter value and thebitstream signalling parameter.

This embodiment, according to the invention, allows for a provision of abitstream representing a multi-channel audio content with compact sideinformation. By providing a common inter-object-correlation bitstreamparameter value, the object-related side information is held compact,while still providing efficient information for a reproduction of themulti-channel audio content with a good hearing impression. In addition,it should be noted that the audio signal encoder described here providesfor the same advantages which have been discussed with respect to theaudio signal decoder.

In an embodiment, the parameter provider is configured to provide thecommon inter-object-correlation bitstream parameter value in dependenceon a ratio between a sum of cross-power terms and a sum of average powerterms. It has been found that such an inter-object-correlation bitstreamparameter value can be computed with moderate computational effort,while still providing an accurate hearing impression in most cases.

In another embodiment according to the invention, the parameter provideris configured to provide a predetermined constant value as the commoninter-object-correlation bitstream parameter value. It has been foundthat in some cases, the provision of a constant value makes sense. Forexample, for certain standard microphone arrangements in certain typesof conference rooms, a constant value may be very well suited torepresent a desired hearing impression. Accordingly, the computationaleffort can be minimized while providing a good hearing impression inmany standard applications of the inventive concept.

In another embodiment, the parameter provider is configured to alsoprovide an object-relationship information describing whether two audioobjects are related to each other. Such an object-relationshipinformation can be exploited by the audio decoder, as discussed above.Accordingly, it can be ensured that the common inter-object-correlationbitstream parameter value is only applied for such audio objects, whichare, indeed, related to each other, but is not applied to entirelyunrelated audio objects.

In an embodiment, the parameter provider is configured to selectivelyevaluate an inter-object-correlation of audio objects for which theobject-relationship information indicates a relationship for acomputation of the common inter-object-correlation bitstream parametervalue. This allows to have a particularly meaningfulinter-object-correlation bitstream parameter value.

Further embodiments according to the invention create a method forproviding an upmix signal representation and a method for providing abitstream representation. These methods are based on the same ideas asthe above-discussed audio decoder and audio encoder.

Another embodiment according to the invention creates a bitstreamrepresenting a multi-channel audio signal. The bitstream comprises arepresentation of a downmix signal combining audio signals of aplurality of audio objects. The bitstream also comprises anobject-related parametric side information describing characteristics ofthe audio objects. The object-related parametric side informationcomprises a bitstream signaling parameter indicating whether thebitstream comprises individual inter-object-correlation bitstreamparameter values or a common inter-object-correlation bitstreamparameter value. Accordingly, the bitstream allows for a flexible usagefor the transmission of different types of audio-channel contents. Inparticular, the bitstream allows for both the transmission of theindividual inter-object-correlation bitstream parameter values or of thecommon inter-object-correlation bitstream parameter value, whichever ismore suited for the auditory scene. Accordingly, the bitstream iswell-suited for handling both cases in which there is a comparativelysmall number of related audio objects for which detailed(object-individual) inter-object-correlation information should betransmitted and for cases in which there is a comparatively large numberof related audio objects for which a transmission of individualinter-object-correlation bitstream parameter values would result in anexcessively high bitrate demand and for which a commoninter-object-correlation bitstream parameter value still allows for areproduction with a good hearing impression.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments according to the invention will subsequently be describedtaking reference to the enclosed Figs. in which:

FIG. 1 shows a block schematic diagram of an audio signal decoderaccording to an embodiment of the invention;

FIG. 2 shows a block schematic diagram of an audio signal encoderaccording to an embodiment of the invention;

FIG. 3 shows a schematic representation of a bitstream according to anembodiment of the invention;

FIG. 4 shows a block schematic diagram of an MPEG SAOC system using asingle inter-object-correlation parameter calculation;

FIG. 5 shows a syntax representation of an SAOC specific configurationinformation, which may be part of a bitstream;

FIG. 6 shows a syntax representation of an SAOC frame information, whichmay be part of a bitstream;

FIG. 7 shows a table representing a parameter quantization of theinter-object-correlation parameter;

FIG. 8 shows a block schematic diagram of a reference MPEG SAOC system;

FIG. 9a shows a block schematic diagram of a reference SAOC system usinga separate decoder and mixer;

FIG. 9b shows a block schematic diagram of a reference SAOC system usingan integrated decoder and mixer; and

FIG. 9c shows a block schematic diagram of a reference SAOC system usingan SAOC-to-MPEG transcoder.

DETAILED DESCRIPTION OF THE INVENTION 1. Audio Signal Decoder Accordingto FIG. 1

In the following, an audio signal decoder 100 will be described takingreference to FIG. 1, which shows a block schematic diagram of such anaudio signal decoder 100.

Firstly, input and output signals of the audio signal decoder 100 willbe described. Subsequently, the structure of the audio signal decoder100 will be described and, finally, the functionality of the audiosignal decoder 100 will be discussed.

The audio signal decoder 100 is configured to receive a downmix signalrepresentation 110, which typically represents a plurality of audioobject signals, for example, in the form of a one-channel audio signalrepresentation or a two-channel audio signal representation.

The audio signal decoder 100 also receives an object-related parametricinformation 112, which typically describes the audio objects, which areincluded in the downmix signal representation 110.

For example, the object-related parametric information 112 describesobject levels of the audio objects, which are represented by the downmixsignal representation 110, using object-level difference values (OLD).

In addition, the object-related parametric information 112 typicallyrepresents inter-object-correlation characteristics of the audioobjects, which are represented by the downmix signal representation 110.The object-related parametric information typically comprises abitstream signalling parameter (also designated with “bsOneIOC” herein),which signals whether the object-rated parametric information comprisesindividual inter-object-correlation bitstream parameter valuesassociated to individual pairs of audio objects or a commoninter-object-correlation bitstream parameter value associated with aplurality of pairs of audio objects. Accordingly, the object-relatedparametric information comprises the individual inter-object-correlationbitstream parameter values or the common inter-object-correlationbitstream parameter value, in accordance with the bitstream signallingparameter “bsOneIOC”.

The object-related parametric information 112 may also comprise downmixinformation describing a downmix of the individual audio objects intothe downmix signal representation. For example, the object-relatedparametric information comprises a downmix gain information DMGdescribing a contribution of the audio object signals to the downmixsignal representation 110. In addition, the object-related parametricinformation may, optionally, comprise a downmix-channel-level-differenceinformation DCLD describing downmix gain differences between differentdownmix channels.

The signal decoder 100 is also configured to receive a renderinginformation 120, for example, from a user interface for inputting saidrendering information. The rendering information describes an allocationof the signals of the audio objects to upmix channels. For example, therendering information 120 may take the form of a rendering matrix (orentries thereof). Alternatively, the rendering information 120 maycomprise a description of a desired rendering position (for example, interms of spatial coordinates) of the audio objects and desiredintensities (or volumes) of the audio objects.

The audio signal decoder 100 provides an upmix signal representation130, which constitutes a rendered representation of the audio objectsignals described by the downmix signal representation and theobject-related parametric information. For example, the upmix signalrepresentation may take the form of individual audio channel signals, ormay take the form of a downmix signal representation in combination witha channel-related parametric side information (for example,MPEG-Surround side information).

The audio signal decoder 100 is configured to provide the upmix signalrepresentation 130 on the basis of the downmix signal representation 110and the object-related parametric information 112 and in dependence onthe rendering information 120. The apparatus 100 comprises anobject-parameter determinator 140, which is configured to obtaininter-object-correlation values (at least) for a plurality of pairs ofrelated audio objects on the basis of the object-related parametricinformation 112. For this purpose, the object-parameter determinator 140is configured to evaluate the bitstream signalling parameter(“bsOneIOC”) in order to decide whether to evaluate individualinter-object-correlation bitstream parameter values to obtain theinter-object-correlation values for a plurality of pairs of relatedaudio objects or to obtain the inter-object-correlation values for aplurality of pairs of related audio objects using a commoninter-object-correlation bitstream parameter value. Accordingly, theobject-parameter determinator 140 is configured to provide theinter-object-correlation values 142 for a plurality of pairs of relatedaudio objects on the basis of individual inter-object-correlationbitstream parameter values if the bitstream signaling parameterindicates that a common inter-object-correlation bitstream parametervalue is not available. Similarly, the object-parameter determinatordetermines the inter-object-correlation values 142 for a plurality ofpairs of related audio objects on the basis of the commoninter-object-correlation bitstream parameter value if the bitstreamsignaling parameter indicates that such a commoninter-object-correlation bitstream parameter value is available.

The object-parameter determinator also typically provides otherobject-related values, like, for example, object-level-difference valuesOLD, downmix-gain values DMG and (optionally)downmix-channel-level-difference values DCLD on the basis of theobject-related parametric information 112.

The audio signal decoder 100 also comprises an signal processor 150,which is configured to obtain the upmix signal representation 130 on thebasis of the downmix signal representation 110 and using theinter-object-correlation values 142 for a plurality of pairs of relatedaudio objects and the rendering information 120. The signal processor150 also uses the other object-related values, likeobject-level-difference values, downmix-gain values anddownmix-channel-level-difference values.

The signal processor 150 may, for example, estimate statisticcharacteristics of a desired upmix signal representation 130 and processthe downmix signal representation such that the upmix signalrepresentation 130 derive from the downmix signal representationcomprises the desired statistic characteristics. Alternatively, thesignal processor 150 may try to separate the audio object signals of theplurality of audio objects, which are combined in the downmix signalrepresentation 110, using the knowledge about the object characteristicsand the downmix process. Accordingly, the signal processor may calculatea processing rule (for example, a scaling rule or a linear combinationrule), which would allow for a reconstruction of the individual audioobject signals or at least of audio signals having similar statisticalcharacteristics as the individual audio object signals. The signalprocessor 150 may then apply the desired rendering to obtain the upmixsignal representation. Naturally, the computation of reconstructed audioobject signals, which approximate the original individual audio objectsignals, and the rendering can be combined in a single processing stepin order to reduce the computational complexity.

To summarize the above, the audio signal decoder is configured toprovide the upmix signal representation 130 on the basis of the downmixsignal representation 110 and the object-related parametric information112 using the rendering information 120. The object-related parametricinformation 112 is evaluated in order to have a knowledge about thestatistical characteristics of the individual audio object signals andof the relationship between the individual audio object signals, whichis needed by the signal processor 150. For example, the object-relatedparametric information 112 is used in order to obtain an estimatedvariance matrix describing estimated covariance values of the individualaudio object signals. The estimated covariance matrix is then applied bythe signal processor 150 in order to determine a processing rule (forexample, as discussed above) for deriving the upmix signalrepresentation 130 from the downmix signal representation 110, wherein,naturally, other object-related information may also be exploited.

The object-parameter determinator 140 comprises different modes in orderto obtain the inter-object-correlation values for a plurality of pairsof related audio objects, which constitutes an important inputinformation for the signal processor 150. In a first mode, theinter-object-correlation values are determined using individualinter-object-correlation bitstream parameter values. For example, theremay be one individual inter-object-correlation bitstream parameter valuefor each pair of related audio objects, such that the object-parameterdeterminator 140 simply maps such an individual inter-object-correlationbitstream parameter value onto one or two inter-object-correlationvalues associated with a given pair of related audio objects. On theother hand, there is also a second mode of operation, in which theobject-parameter determinator 140 merely reads a single commoninter-object-correlation bitstream parameter value from the bitstreamand provides a plurality of inter-object-correlation values for aplurality of different pairs of related audio objects on the basis ofthis single common inter-object-correlation bitstream parameter value.Accordingly, the inter-object-correlation values for a plurality ofpairs of related audio objects may, for example, be identical to thevalue represented by the single common inter-object-correlationbitstream parameter value, or may be derived from the same commoninter-object-correlation bitstream parameter value. The object-parameterdeterminator 140 is switchable between said first mode and said secondmode in dependence on the bitstream signalling parameter (“bsOneIOC”).

Accordingly, there are different modes for the provision of theinter-object-correlation values, which can be applied by theobject-parameter determinator 140. If there is a relatively small numberof pairs of related audio objects, the inter-object-correlation valuesfor said pairs of related audio objects are typically (in dependence onthe bitstream signaling parameter) determined individually by theobject-parameter determinator, which allows for a particularly preciserepresentation of the characteristics of said pairs of related audioobjects and, consequently, brings along the possibility ofreconstructing the individual audio object signals with good accuracy inthe signal processor 150. Thus, it is typically possible to provide agood hearing impression in such a case in which only correlationsbetween a comparatively small number of pairs of related audio objectsare relevant.

The second mode of operation of the object-parameter determinator, inwhich a common inter-object-correlation bitstream parameter value isused to obtain inter-object-correlation values for a plurality of pairsof related audio objects, is typically used in cases in which there arenon-negligible correlations between a plurality of pairs of audioobjects. Such cases could conventionally not be handled withoutexcessively increasing the bitrate of a bitstream representing both thedownmix signal representation 110 and the object-related parametricinformation 112. The usage of a common inter-object-correlationbitstream parameter value brings along specific advantages if there arenon-negligible correlations between a comparatively large number ofpairs of audio objects, which correlations do not comprise acousticallysignificant variations. In this case, it is possible to consider thecorrelations with moderate bitrate effort, which brings along areasonably good compromise between bitrate requirement and quality ofthe hearing impression.

Accordingly, the audio signal decoder 100 is capable of efficientlyhandling different situations, namely situations in which there are onlya few pairs of related audio objects, the inter-object-correlation ofwhich should be taken into consideration with high precision, andsituations in which there is a large number of pairs of related audioobjects, the inter-object-correlations of which should not be neglectedentirely but have some similarity. The audio signal decoder 100 iscapable of handling both situations with a good quality of the hearingimpression.

2. Audio Signal Encoder According to FIG. 2

In the following, an audio signal encoder 200 will be described takingreference to FIG. 2, which shows a block schematic diagram of such anaudio signal encoder 200.

The audio signal encoder 200 is configured to receive a plurality ofaudio object signals 210 a to 210N. The audio object signals 210 a to210N may, for example, be one-channel signals or two-channel signalsrepresenting different audio objects.

The audio signal encoder 200 is also configured to provide a bitstreamrepresentation 220, which describes the auditory scene represented bythe audio object signals 210 a to 210N in a compact andbitrate-efficient manner.

The audio signal encoder 200 comprises a downmixer 220, which isconfigured to receive the audio object signals 210 a to 210N and toprovide a downmix signal 232 on the basis of the audio object signals210 a to 210N. The downmixer 230 is configured to provide the downmixsignal 232 in dependence on downmix parameters describing contributionsof the audio object signals 210 a to 210N to the one or more channels ofthe downmix signal.

The audio signal encoder also comprises a parameter provider 240, whichis configured to provide a common inter-object-correlation bitstreamparameter value 242 associated with a plurality of pairs of relatedaudio object signals 210 a to 210N. The parameter provider 240 is alsoconfigured to provide a bitstream signalling parameter 244 indicatingthat the common inter-object-correlation bitstream parameter value 242is provided instead of a plurality of individualinter-object-correlation bitstream parameters (individually associatedwith different pairs of audio objects).

The audio signal encoder 200 also comprises a bitstream formatter 250,which is configured to provide a bitstream representation 250 comprisinga representation of the downmix signal 232 (for example, an encodedrepresentation of the downmix signal 232), a representation of thecommon inter-object-correlation bitstream parameter value 242 (forexample, a quantized and encoded representation thereof) and thebitstream signalling parameter 244 (for example, in the form of aone-bit parameter value).

The audio signal decoder 200 consequently provides a bitstreamrepresentation 220, which represents the audio scene described by theaudio object signals 210 a to 210N with good accuracy. In particular,the bitstream representation 220 comprises a compact side information ifmany of the audio object signals 210 a to 210N are related to eachother, i.e. comprise a non-negligible inter-object-correlation. In thiscase, the common inter-object-correlation bitstream parameter value 242is provided instead of individual inter-object-correlation bitstreamparameter values individually associated with pairs of audio objects.Accordingly, the audio signal encoder can provide a compact bitstreamrepresentation 220 in any case, both if there are many related pairs ofaudio object signals 210 a to 210N and if there are only a few pairs ofrelated audio object signals 210 a to 210N. In particular the bitstreamrepresentation 220 may comprise the information needed by the audiosignal decoder 100 as an input information, namely the downmix signalrepresentation 110 and the object-related parametric information 112.Thus, the parameter provider 240 may be configured to provide additionalobject-related parametric information describing the audio objectsignals 210 a to 210N as well as the downmix process performed by thedownmixer 230. For example, the parameter provider 240 may additionallyprovide an object-level-difference information OLD describing the objectlevels (or object-level differences) of the audio object signals 210 ato 210N. Furthermore, the parameter provider 240 may provide adownmix-gain information DMG describing downmix gains applied to theindividual audio object signals 210 a to 210N when forming the one ormore channels of the downmix signal 232.Downmix-channel-level-difference values DCLD, which describe downmixgain differences between different channels of the downmix signal 232,may also, optionally, be provided by the parameter provider 240 forinclusion into the bitstream representation 220.

To summarize the above, the audio signal encoder efficiently providesthe object-related parametric information needed for a reconstruction ofthe audio scene described by the audio object signals 210 a to 210N witha good hearing impression, wherein a compact commoninter-object-correlation bitstream parameter value is used if there is alarge number of related pairs of audio objects. This is signaled usingthe bitstream signaling parameter 244. Thus, an excessive bitstream loadis avoided in such a case.

Further details regarding the provision of a bitstream representationwill be described below.

3. Bitstream According to FIG. 3

FIG. 3 shows a schematic representation of a bitstream 300, according toan embodiment of the invention.

The bitstream 300 may, for example, serve as an input bitstream of theaudio signal decoder 100, carrying the downmix signal representation 110and the object-related parametric information 112. The bitstream 300 maybe provided as an output bitstream 220 by the audio signal encoder 200.

The bitstream 300 comprises a downmix signal representation 310, whichis a representation of a one-channel or multi-channel downmix signal(for example, the downmix signal 232) combining audio signals of aplurality of audio objects. The bitstream 300 also comprisesobject-related parametric side information 320 describingcharacteristics of the audio objects, the audio object signals of whichare represented, in a combined form, by the downmix signalrepresentation 310. The object-related parametric side information 320comprises a bitstream signaling parameter 322 indicating whether thebitstream comprises individual inter-object-correlation bitstreamparameters (individually associated with different pairs of audioobjects) or a common inter-object-correlation bitstream parameter value(associated with a plurality of different pairs of audio objects). Theobject-related parametric side information also comprises a plurality ofindividual inter-object-correlation bitstream parameter values 324 a,which is indicated by a first state of the bitstream signaling parameter322, or a common inter-object-correlation bitstream parameter value,which is indicated by a second state of the bitstream signalingparameter 322.

Accordingly, the bitstream 300 may be adapted to the relationshipcharacteristics of the audio object signals 210 a to 210N by adaptingthe format of the bitstream 300 to contain a representation ofindividual inter-object-correlation bitstream parameter values or arepresentation of a common inter-object-correlation bitstream parametervalue.

The bitstream 300 may, consequently, provide the chance of efficientlyencoding different types of audio scenes with a compact sideinformation, while maintaining the change of obtaining a good hearingimpression for the case that there are only a few strongly-correlatedaudio objects.

Further details regarding the bitstream will subsequently be discussed.

4. The MPEG SAOC System According to FIG. 4

In the following, an MPEG SAOC system using a single IOC parametercalculation will be described taking reference to FIG. 4.

The MPEG SAOC system 400 according to FIG. 4 comprises an SAOC encoder410 and an SAOC decoder 420.

The SAOC encoder 410 is configured to receive a plurality of, forexample, L audio object signals 420 a to 420N. The SAOC encoder 410 isconfigured to provide a downmix signal representation 430 and a sideinformation 432, which are advantageously, but not necessarily, includedin a bitstream.

The SAOC encoder 410 comprises an SAOC downmix processing 440, whichreceives the audio object signals 420 a to 420N and provides the downmixsignal representation 430 on the basis thereof. The SAOC encoder 410also comprises a parameter extractor 444, which may receive the objectsignals 420 a to 420N and which may, optionally, also receive aninformation about the SAOC downmix processing 440 (for example, one ormore downmix parameters). The parameter extractor 444 comprises a singleinter-object-correlation calculator 448, which is configured tocalculate a single (common) inter-object-correlation value associatedwith a plurality of pairs of audio objects. In addition, the singleinter-object-correlation calculator 448 is configured to provide asingle inter-object-correlation signaling 452, which indicates if asingle inter-object-correlation value is used instead ofobject-pair-individual inter-object-correlation values. The singleinter-object-correlation calculator 448 may, for example, decide on thebasis of an analysis of the audio object signals 420 a to 420N whether asingle common inter-object-correlation value (or, alternatively, aplurality of individual inter-object-correlation parameter valuesassociated individually with pairs of audio object signals) areprovided. However, the single inter-object-correlation calculator 448may also receive an external control information determining whether acommon inter-object-correlation value (for example, a bitstreamparameter value) or individual inter-object-correlation values (forexample, bitstream parameter values) should be calculated.

The parameter extractor 444 is also configured to provide a plurality ofparameters describing the audio object signals 420 a to 420N, like, forexample, object-level difference parameters. The parameter extractor 444is also advantageously configured to provide parameters describing thedownmix, like, for example, a set of downmix-gain parameters DMG and aset of downmix-channel-level-difference parameters DCLD.

The SAOC encoder 410 comprises a quantization 456, which quantizes theparameters provided by the parameter extractor 444. For example, thecommon inter-object-correlation parameter may be quantized by thequantization 456. In addition, the object-level-difference parameters,the downmix-gain parameters and the downmix-channel-level-differenceparameters may also be quantized by the quantization 456. Accordingly,the quantized parameters are obtained by the quantization 456.

The SAOC encoder 410 also comprises a noiseless coding 460, which isconfigured to encode the quantized parameters provided by thequantization 456. For example, the noiseless coding may noiselesslyencode the quantized common inter-object-correlation parameter and alsothe other quantized parameters (for example, OLD, DMG and DCLD).

Accordingly, the SAOC decoder 410 provides the side information 432 suchthat the side information comprises the single IOC signaling 452 (whichmay be considered as a bitstream signaling parameter) and thenoiselessly-coded parameters provided by the noiseless coding 480 (whichmay be considered as bitstream parameter values).

The SAOC decoder 420 is configured to receive the side information 432provided by the SAOC encoder 410 and the downmix signal representation430 provided by the SAOC encoder 410.

The SAOC decoder 420 comprises a noiseless decoding 464, which isconfigured to reverse the noiseless coding 460 of the side information432 performed in the encoder 410. The SAOC decoder 420 also comprises ade-quantization 468, which may also be considered as an inversequantization (even though, strictly speaking, quantization is notinvertible with perfect accuracy), wherein the de-quantization 468 isconfigured to receive the decoded side information 466 from thenoiseless decoding 464. The de-quantization 468 provides the dequantizedparameters 470, for example, the decoded and de-quantized commoninter-object-correlation value provided by the singleinter-object-correlation calculator 448 and also decoded andde-quantized object-level difference values OLD, decoded andde-quantized downmix-gain values DMG and decoded and de-quantizeddownmix-channel-level-difference values DCLD. The SAOC decoder 420 alsocomprises a single inter-object-correlation expander 474, which isconfigured to provide a plurality of inter-object-correlation valuesassociated with a plurality of pairs of related audio objects on thebasis of the common inter-object-correlation value. However, it shouldbe noted that the single inter-object-correlation expander 474 may bearranged before the noiseless decoding 464 and the de-quantization 468in some embodiments. For example, the single inter-object-correlationexpander 474 may be integrated into a bitstream parser, which receives abitstream comprising both the downmix signal representation 430 and theside information 432.

The SAOC decoder 420 also comprises an SAOC decoder processing andmixing 480, which is configured to receive the downmix signalrepresentation 430 and the decoded parameters included (in an encodedform) in the side information 432. Thus, the SAOC decoder processing andmixing 480 may, for example, receive one or two inter-object-correlationvalues for every pair of (different) audio objects, wherein the one ortwo inter-object-correlation values may be zero for non-related audioobjects and non-zero for related audio objects. In addition, the SAOCdecoder processing and mixing 480 may receive object-level-differencevalues for every audio object. In addition, the SAOC decoder processingand mixing 480 may receive downmix-gain values and (optionally)downmix-channel-level-difference values describing the downmix performedin the SAOC downmix processing 440. Accordingly, the SAOC decoderprocessing and mixing 480 may provide a plurality of channel signals 484a to 484N in dependence on the downmix signal representation 430, theside information parameters included in the side information 432 and aninteraction information 482, which describes a desired rendering of theaudio objects. However, it should be noted that the channels 484 a to484N may be represented either in the form of individual audio channelsignals or in the form of a parametric representation, like, forexample, a multi-channel representation according to the MPEG Surroundstandard (comprising, for example, an MPEG Surround downmix signal andchannel-related MPEG Surround side information). In other words, both anindividual channel audio signal representation and a parametricmulti-channel audio signal representation will be considered as an upmixsignal representation within the present description.

In the following, some details regarding the functionality of the SAOCencoder 410 and of the SAOC decoder 420 will be described.

The SAOC side information, which will be discussed in the following,plays an important role in the SAOC encoding and the SAOC decoding. TheSAOC side information describes the input objects (audio objects) bymeans of their time/frequency variant covariance matrix. The N objectsignals 420 a to 420N (also sometimes briefly designated as “objects”)can be written as rows in a matrix:

$S = \begin{bmatrix}{s_{1}(0)} & {s_{1}(1)} & \ldots & {s_{1}\left( {L - 1} \right)} \\{s_{2}(0)} & {s_{2}(1)} & \ldots & {s_{2}\left( {L - 1} \right)} \\\vdots & \vdots & \ddots & \vdots \\{s_{N}(0)} & {s_{N}(1)} & \ldots & {s_{N}\left( {L - 1} \right)}\end{bmatrix}$

Here, the entries s_(i)(1) designate spectral values of an audio objecthaving audio object index for a plurality of temporal portions havingtime indices 1. A signal block of L samples represents the signal in atime and frequency interval which is a part of the perceptuallymotivated tiling of the time-frequency plane that is applied for thedescription of signal properties.

Hence, the covariance matrix is given as

${SS}^{*} = \begin{bmatrix}\left. ||s_{1} \right.||^{2} & \rho_{12} & \ldots & \rho_{1\; N} \\\rho_{21} & \left. ||s_{2} \right.||^{2} & \ldots & \rho_{2\; N} \\\vdots & \vdots & \ddots & \vdots \\\rho_{N\; 1} & \rho_{N\; 2} & \ldots & \left. ||s_{N} \right.||^{2}\end{bmatrix}$with(ρ_(mn)=ρ_(nm)*).

The covariance matrix is typically used by the SAOC decoder processingand mixing 480 in order to obtain the channel signals 484 a to 484N.

The diagonal elements can directly be reconstructed at the SAOC decoderside with the OLD data, and the non-diagonal elements are given by theinter-object-correlations (IOCs) asρ_(mn) =∥s _(m) ∥·∥s _(n)∥·IOC_(mn).

It should be noted that the object-level-difference values describes_(m) and s_(n).

The number of inter-object-correlation values needed to convey the wholecovariance matrix is N*N/2−N/2. As this number can get large (forexample, for a large number N of object signals), resulting in a highbit demand, the SAOC encoder 410 (as well as the audio signal encoder200) can, optionally, transmit only selected inter-object-correlationvalues for object pairs, which are signaled to be “related to” eachother. This optional “related to” information is, for example,statically conveyed in an SAOC-specific configuration syntax element ofthe bitstream, which may, for example, be designated with“SAOCSpecificConfig( )”. Objects, which are not related to each other,are, for example, assumed to be uncorrelated, i.e. theirinter-object-correlation is equal to zero.

However, there exist application scenarios where all objects (or almostall objects) are related to each other. An example of such anapplication scenario is a telephone conference with a microphone setupand room acoustics with a high degree of inter-microphone cross talk. Inthese cases, the transmission of all IOC values would be needed (if theabove-mentioned conventional mechanism was used), but usually wouldexceed the desired bit budget. As an alternative, assuming that allobjects are uncorrelated would induce a large error in the model and,therefore, would yield sub-optimal audio quality of the rendered scene.

The underlying assumption of the proposed approach is that for certainSAOC application scenarios, uncorrelated sound sources result incorrelated SAOC input objects due to the acoustic environment they arelocated in and due to the applied recording techniques.

Considering a telephone conference setup, for instance, the impact ofthe room reverberation and the imperfect isolation of the individualspeakers leads to correlated SAOC objects although the talking of theindividual subjects is uncorrelated. These acoustical circumstances andthe resulting correlation can be approximately described with a singlefrequency- and time-varying value.

Thus, the proposed method successfully circumvents the high bitratedemand of conveying all desired object correlations. This is done bycalculating a single time/frequency dependent single IOC value in adedicated “single IOC calculator” module 448 in the SAOC encoder (seeFIG. 4). Use of the “single IOC” feature is signaled in the SAOCinformation (for example, using the bitstream signaling parameter“bsOneIOC”). The single IOC value per time/frequency tile is thentransmitted instead of all separate IOC values (for example, using thecommon inter-object-correlation bitstream parameter value).

In a typical application, the bitstream header (for example, the“SAOCSpecificConfig( )” element according to the non-prepublished SAOCStandard [SAOC]) includes one bit indicating if “single IOC” signalingor “normal” IOC signaling is used. Some details regarding this issuewill be discussed below.

The payload frame data (for example, the “SAOCFrame( )” element in thenon-prepublished SAOC Standard [SAOC]) then includes IOCs common for allobjects or several IOCs depending on the “single IOCs” or “normal” mode.

Hence, a bitstream parser (which may be part of the SAOC decoder) forthe payload data in the decoder could be designed according to theexample below (which is formulated in a pseudo C code):

if (iocMode == SINGLE_IOC) { readIocDataFromBitstream(1); } else {readIocDataFromBitstream (numberOfTransmittedIocs); }

According to the above example, the bitstream parser checks whether aflag “iocMode” (also designated with “bsOneIOC” in the following)indicates that there is only a single inter-object-correlation bitstreamparameter value (which is signaled by the parameter value “SINGLE_IOC”).If the bitstream parser finds that there is only a singleinter-object-correlation value, the bitstream parser reads oneinter-object-correlation data unit (i.e., one inter-object-correlationbitstream parameter value) from the bitstream, which is indicated by theoperation “readIocDataFromBitstream(1)”. If, in contrast, the bitstreamparser finds that the flag “iocMode” does not indicate the usage of asingle (common) inter-object-correlation value, the bitstream parserreads a different number of inter-object-correlation data units (e.g.,inter-object-correlation bitstream parameter values) from the bitstream,which is indicated by the function “readIocDataFromBitstream(numberOfTransmittedIocs)”). The number (“numberOfTransmittedIocs”) ofinter-object-correlation data units read in this case is typicallydetermined by a number of pairs of related audio objects.

Alternatively, the “single IOC” signalling can be present in the payloadframe (for example, in the so-called “SAOCFrame( )” element in thenon-prepublished SAOC Standard) to enable dynamical switching betweensingle IOC mode and normal IOC mode on a per-frame basis.

5. Encoder-Sided Implementation of the Calculation of a CommonInter-Object-Correlation Bitstream Parameter

In the following, some implementations for the single IOC (IOC_(single))calculation will be described.

5.1. Calculation Using Cross-Power Terms

In an embodiment of the SAOC encoder 410, the commoninter-object-correlation bitstream parameter value IOC_(single) can becomputed according to the following equation:

${IOC}_{single} = {{Re}\left\{ \frac{\sum\limits_{i = 1}^{N}\;{\sum\limits_{j = {i + 1}}^{N}\;{nrg}_{ij}}}{\sum\limits_{i = 1}^{N}\;{\sum\limits_{j = {i + 1}}^{N}\;\sqrt{{nrg}_{ii}{nrg}_{jj}}}} \right\}}$with the cross power terms

${nrg}_{ij} = {\sum\limits_{n}\;{\sum\limits_{k}\;{s_{i}^{n,k}\left( s_{j}^{n,k} \right)}^{*}}}$where n and k are the time and frequency instances (or time andfrequency indices) for which the SAOC parameter applies.

In other words, the common inter-object-correlation bitstream parametervalue IOC_(single) can be computed in dependence on a ratio between asum of cross-power terms nrg_(ij) (wherein the object index i istypically different from the object index j) and a sum of average energyvalues √{square root over (nrg_(ii)nrg_(jj))} (which average energyvalues represent, for example, a geometrical mean between the energyvalues nrg_(ii) and nrg_(jj)).

The summation may be performed, for example, for all pairs of differentaudio objects, or for pairs of related audio objects only.

The cross-power term nrg_(ij) may, for example, be formed as a sum overcomplex conjugate products (with one of the factors beingcomplex-conjugated) of spectral coefficients s_(i) ^(n,k), s_(j) ^(n,k)associated with the audio object signals of the pair of audio objectsunder consideration for a plurality of time instances (having timeindices n) and/or a plurality of frequency instances (having frequencyindices k).

A real part of said ratio may be formed (for example, by an operationRe{ }) in order to have a real-valued common inter-object-correlationbitstream parameter value IOC_(single), as shown in the above equation.

5.2. Usage of a Constant Value

In another embodiment, a constant value c may be chosen to obtain thecommon inter-object-correlation bitstream parameter value IOC_(single)in accordance withIOC_(single) =c,with c being a constant.

This constant c could, for example, describe a time- andfrequency-independent cross talk of a room with specific acoustics(amount of reverb) where a telephone conference takes place.

The constant c may, for example, be set in accordance with an estimationof the room acoustics, which may be performed by the SAOC encoder.Alternatively, the constant c may be input via a user interface, or maybe predetermined in the SAOC encoder 410.

6. Decoder-Sided Determination of the Inter-Object-Correlation Valuesfor all Object Pairs

In the following, it will be described how the inter-object-correlationvalues for all object pairs can be obtained.

At the decoder side (for example, in the SAOC decoder 420), the singleinter-object-correlation (bitstream) parameter (IOC_(single)) is used todetermine the inter-object-correlation values for all object pairs. Thisis done, for example, in the “Single IOC Expander” module 474 (see FIG.4).

An advantageous method is a simple copy operation. The copying can beapplied with or without considering the “related to” informationconveyed, for example, in the SAOC bitstream header (for example, in theportion “SAOCSpecificConfiguration( )”).

In an embodiment, a copying without “related to” information (i.e.,without transferring or considering a “related to” information) may beperformed in the following manner:IOC_(mn)=IOC_(single), for all m, n with m≠n.

Thus, all inter-object-correlation values for pairs of different audioobjects are set to the common inter-object-correlation (bitstream)parameter value.

In another embodiment, a copying with “related to” information (i.e.,taking into consideration the “related to” information) is performed,for example, in the following manner:

${IOC}_{mn} = \left\{ \begin{matrix}{IOC}_{single} & {,{{for}\mspace{14mu}{all}\mspace{14mu} m},{{{n\mspace{14mu}{with}\mspace{14mu} m} \neq {n\mspace{14mu}{and}\mspace{14mu}{{relatedTo}\left( {m,n} \right)}}} = 1}} \\0 & {,{{for}\mspace{14mu}{all}\mspace{14mu} m},{{{n\mspace{14mu}{with}\mspace{14mu} m} \neq {n\mspace{14mu}{and}\mspace{14mu}{{relatedTo}\left( {m,n} \right)}}} = 0}}\end{matrix} \right.$

Accordingly, one or even two inter-object-correlation values associatedwith a pair of audio objects (having audio object indices m and n) areset to the value IOC_(single) specified, for example, by the commoninter-object-correlation bitstream parameter value, if the objectrelationship information “relatedTo(m,n)” indicates that said audioobjects are related to each other. Otherwise, i.e. if the objectrelationship information “relatedTo(m,n)” indicates that the audioobjects of a pair of audio objects are not related, one or even twointer-object-correlation values associated with the pair of audioobjects are set to a predetermined value, for example, to zero.

However, different distribution methods are possible, for example,taking the object powers into account. For example,inter-object-correlation values relating to objects with relatively lowpower could be set to high values, such as 1 (full correlation), tominimize the influence of the decorrelation filter in the SAOC decoder.

7. Decoder Concept Using Bitstream Elements According to FIGS. 5 and 6

In the following, a decoder concept of an audio signal decoder using thebitstream syntax elements according to FIGS. 5 and 6 will be described.It should be noted here that the bitstream syntax and bitstreamevaluation concept, which will be described with reference to FIGS. 5and 6, can be applied, for example, in the audio signal decoder 100according to FIG. 1 and in the audio signal decoder 420 according toFIG. 4. In addition, it should be noted that the audio signal encoder200 according to FIG. 2 and the audio signal decoder 410 according toFIG. 4 can be adapted to provide bitstream syntax elements as discussedwith respect to FIGS. 5 and 6.

Accordingly, the bitstream comprising the downmix signal representation110 and the object-related parametric information 112 and/or thebitstream representation 220 and/or the bitstream 300 and/or a bitstreamcomprising the downmix information 430 and the side information 432, maybe provided in accordance with the following description.

An SAOC bitstream, which may be provided by the above-described SAOCencoders and which may be evaluated by the above-described SAOC decodersmay comprise an SAOC specific configuration portion, which will bedescribed in the following taking reference to FIG. 5, which shows asyntax representation of such an SAOC specific configuration portion“SAOCSpecificConfig( )”.

The SAOC specific configuration information comprises, for example,sampling frequency configuration information, which describes a samplingfrequency used by an audio signal encoder and/or to be used by an audiosignal decoder. The SAOC specific configuration information alsocomprises a low delay mode configuration information, which describeswhether a low delay mode has been used by an audio signal encoder an/orshould be used by an audio signal decoder. The SAOC specificconfiguration information also comprises a frequency resolutionconfiguration information, which describes a frequency resolution usedby an audio signal encoder and/or to be used by an audio signal decoder.The SAOC specific configuration information also comprises a framelength configuration information describing a frame length of audioframes used by the SAOC encoder and/or to be used by the SAOC decoder.The SOAC specific configuration information also comprises an objectnumber configuration information which describes a number of audioobjects. This object number configuration information, which is alsodesignated with “bsNumObjects”, for example describes the value N, whichhas been used above.

The SAOC specific configuration information also comprises an objectrelationship configuration information. For example, there may be onebitstream bit for every pair of different audio objects. However, therelationship of audio objects may be represented, for example, by asquare N×N matrix having a one-bit entry for every combination of audioobjects. Entries of said matrix describing the relationship of an objectwith itself, i.e., diagonal elements, may be set to one, which indicatesthat an object is related to itself. Two entries, namely a first entryhaving a first index i and a second index j, and a second entry having afirst index j and a second index i, may be associated with each pair ofdifferent audio objects having audio object indices i and j.Accordingly, a single bitstream bit determines the values of two entriesof the object relationship matrix, which are set to identical values.

As can be seen, a first audio object index i runs from i=0 toi=bsNumObjects (outer for-loop). A diagonal entry “bsRelatedTo[i][i]” isset to one for all values of i. For a first audio object index i, bitsdescribing a relationship between audio object i and audio objects j(having audio object index j) are included in the bit stream for j=i+1to j=bsNumObjects. Accordingly, entries of the relationship matrix“bsRelatedTo[i][j]”, which describe a relationship between the audioobjects having audio object indices i and j, are set to the value givenin the bit stream. In addition, an object relationship matrix entry“bsRelatedTo[j][i]” is set to the same value, i.e., to the value of thematrix entry “bsRelatedTo[i][j]”. For details, reference is made to thesyntax representation of FIG. 5.

The SAOC specific configuration information also comprises an absoluteenergy transmission configuration information, which describes whetheran audio encoder has included an absolute energy information into thebit stream, and/or whether an audio decoder should evaluate an absoluteenergy transmission configuration information included in the bitstream.

The SAOC specific configuration information also comprises adownmix-channel-number configuration information, which describes anumber of downmix channels used by the audio encoder and/or to be usedby the audio decoder. The SAOC specific configuration information mayalso comprise additional configuration information, which is notrelevant for the present application, and which can optionally beomitted.

The SAOC specific configuration information also comprises a commoninter-object-correlation configuration information (also designated as a“bitstream signaling parameter” herein) which describes whether a commoninter-object-correlation bitstream parameter value is included in theSAOC bitstream, or whether object-pair-individualinter-object-correlation bitstream parameter values are included in theSAOC bitstream. Said common inter-object-correlation configurationinformation may, for example, be designated with “bsOneIOC, and may be aone-bit value.

The SAOC specific configuration information may also comprise adistortion control unit configuration information.

In addition, the SAOC specific configuration information may compriseone or more fill bits, which are designated with “ByteAlign( )”, andwhich may be used to adjust the lengths of the SAOC specificconfiguration information. In addition, the SAOC specific configurationinformation may comprise optional additional configuration information“SAOCExtensionConfig( )” which is not of relevance for the presentapplication and which will not be discussed here for this reason.

It should be noted here that the SAOC specific configuration informationmay comprise more or less than the above described configurationinformation. In other words, some of the above described configurationinformation may be omitted in some embodiments, and additionalconfiguration information may also be also included in some embodiments.

However, it should be noted that the SAOC specific configurationinformation may, for example, be included once per piece of audio in anSAOC bitstream. However, the SAOC specific configuration information mayoptionally be included more often in the bitstream. Nevertheless, theSAOC specific configuration information is typically provided for aplurality of SAOC frames, because the SAOC specific configurationinformation provides a significant bit load overhead.

In the following, the syntax of an SAOC frame will be described takingreference to FIG. 6, which shows a syntax representation of such an SAOCframe. The SAOC frame comprises encoded object-level-difference valuesOLD, which may be included band-wise and per audio object.

The SAOC frame also comprises encoded absolute energy values NRG, whichmay be considered as optional, and which may be included band-wise.

The SAOC frame also comprises encoded inter-object-correlation valuesIOC, which may be provide band-wise, i.e., separately for a plurality offrequency bands, and for a plurality of combinations of audio objects.

In the following, the bitstream will be described with respect to theoperations which may be performed by a bitstream parser parsing thebitstream.

The bitstream parser may, for example, initialize variables k, iocldx1,iocldx2 to a value of zero in a first preparatory step.

Subsequently, the bitstream parser may perform a parsing for a pluralityof values of the first audio object index i between i=0 andi=bsNumObjects (outer for-loop). The bitstream parser may, for example,set an inter-object-correlation index value idxIoc[i][i] describing arelationship between the audio object having audio object index i anditself to zero which indicates a full correlation.

Subsequently, a bitstream parser may evaluate the bitstream for values jof a second audio object index between i+1 and bsNumObjects. If audioobjects having audio object indices and j are related, which isindicated by a non-zero value of the object relationship matrix entry“bsRelatedTo[i][j]”, the bitstream parser performs an algorithm 610, andotherwise, the bitstream parser sets the inter-object-correlation indexassociated with the audio objects having audio object indices i and j tofive (operation “idxIOC[i][j]=5”), which describes a zero correlation.Thus, for pairs of audio objects, for which the object relationshipmatrix indicates no relationship, the inter-object-correlation value isset to zero. For related pairs of audio objects, however, the bitstreamsignaling parameter “bsOneIOC”, which is included in the SAOC specificconfiguration, is evaluated to decide how to proceed. If the bitstreamsignaling parameter “bsOneIOC” indicates that there areobject-pair-individual inter-object-correlation bitstream parametervalues, a plurality of inter-object-relationship indices idxIOC[i][j](which may be considered as inter-object-relationship bitstreamparameter values) are extracted from the bitstream for “numBands”frequency bands using the function “EcDataSaoc”, wherein said functionmay be used to decode the inter-object-relationship indices.

However, if the bitstream signaling parameter “bsOneIOC” indicated thata common inter-object-correlation bitstream parameter value is used fora plurality of pairs of audio objects, and id the bitstream parameter“bsRelatedTo[i][j]” indicates that the audio objects having audio objectindices i and j are related, a single set of a plurality ofinter-object-correlation indices “idxIOC[i][j]” is read from thebitstream using the function “EcDataSaoc” for a plurality of numBandsfrequency bands, wherein only a single inter-object-correlation index isread for any given frequency band. However upon re-execution of thealgorithm 610, a previously read inter-object-correlation indexidxIOC[iocldx1][iocldx2] is copied without evaluating the bitstream.This is ensured by use of the variable k, which is initialized to zeroand incremented upon evaluation of the first set ofinter-object-correlation indices idxIOC[i][ ].

To summarize, for each combination of two audio objects, it is firstevaluated whether the two audio objects of such a combination aresignaled as being related to each other (for example, by checkingwhether the value “bsRelatedTo[i][j]” takes the value zero or not). Ifthe audio objects of the pair of audio objects are related, the furtherprocessing 610 is performed. Otherwise, the value “idxIOC[i][j]”associated to this pair of (substantially unrelated) audio objects isset to a predetermined value, for example, to a predetermined valueindicating a zero inter-object-correlation.

In the processing 610, a bitstream value is read from the bitstream forevery pair of audio objects (which is signaled to comprise related audioobjects) if the signaling “bsOneIOC” is inactive. Otherwise, i.e., ifthe signaling “bsOneIOC” is active, only one bitstream value is read forone pair of audio objects, and the reference to said single pair ismaintained by setting the index values iocldx1 and iocldx2 to point atthis read out value. The single read out value is reused for other pairsof audio objects (which are signaled as being related to each other) ifthe signaling “bsOneIOC” is active.

Finally, it is also ensured that a same inter-object-correlation indexvalue is associated to both combinations of two given different audioobjects, irrespective of which of the two given audio objects is thefirst audio object and which of the two given audio objects is thesecond audio object.

In addition, it should be noted that the SAOC frame typically comprisesthe encoded downmix gain values (DMG) on a per-audio-object basis.

In addition, the SAOC frame typically comprises encodeddownmix-channel-level-differences (DCLD), which may optionally beincluded on a per-audio-object basis.

The SAOC frame further optionally comprises encodedpost-processing-downmix-gain values (PDG), which may be included in aband wise-manner and per downmix channel.

In addition, the SAOC frame may comprise encoded distortion-control-unitparameters, which determine the application of distortion controlmeasures.

Moreover, the SAOC frame may comprise one or more fill bits “ByteAlign()”.

Furthermore, an SAOC frame may comprise extension data“SAOCExtensionFrame( )”, which, however, are not relevant for thepresent application and will not be discussed in detail here for thisreason.

Taking reference now to FIG. 7, an example for an advantageousquantization of the inter-object-correlation parameter will bedescribed.

As can be seen, a first row 710 of a table of FIG. 7 describes thequantization index idx, which is in a range between zero and seven. Thisquantization index may be allocated to the variable “idxIOC[i][j]”. Asecond row 720 of the table of FIG. 7 shows the associated inter objectcorrelation value, and are in a range between −0.99 and 1. Accordingly,the values of the parameters “idxIOC[i][j]” may be mapped onto inverselyquantized inter-object-correlation values using the mapping of the tableof FIG. 7.

To conclude, an SAOC configuration portion “SAOCSpecificConfig( )”advantageously comprises a bitstream parameter “bsOneIOC” whichindicates if only a single IOC parameter is conveyed common to allobjects which have relation with each other, signaled by“bsRelatedTo[i][j]=1”. The inter-object-correlation values are includedin the bitstream in encoded form “EcDataSaoc (IOC,k,numBands)”. An array“idxIOC[i][j]” is filled on the basis of one or more encodedinter-object-correlation values. The entries of the array “idxIOC[i][j]”are mapped onto inversely quantized values using the mapping table ofFIG. 7, to obtain inversely quantized inter-object-correlation values.The inversely quantized inter-object-correlation values, which aredesignated with IOC_(i,j), are used to obtain entries of a covariancematrix. For this purpose, inversely quantized object-level-differenceparameters are also applied, which are designated with OLD_(i).

The covariance matrix E of size N×N with elements e_(i,j) represents anapproximation of the original signal covariance matrix E≈SS* and isobtained from the OLD and IOC parameters ase ^(i,j)=√{square root over (OLD_(i)OLD_(j))}IOC_(i,j).

7. Implementation Alternatives

Although some aspects have been described in the context of anapparatus, it is clear that these aspects also represent a descriptionof the corresponding method, where a block or device corresponds to amethod step or a feature of a method step. Analogously, aspectsdescribed in the context of a method step also represent a descriptionof a corresponding block or item or feature of a correspondingapparatus. Some or all of the method steps may be executed by (or using)a hardware apparatus, like for example, a microprocessor, a programmablecomputer or an electronic circuit. In some embodiments, some one or moreof the most important method steps may be executed by such an apparatus.

The inventive encoded audio signal can be stored on a digital storagemedium or can be transmitted on a transmission medium such as a wirelesstransmission medium or a wired transmission medium such as the Internet.

Depending on certain implementation requirements, embodiments of theinvention can be implemented in hardware or in software. Theimplementation can be performed using a digital storage medium, forexample a floppy disk, a DVD, a Blu-Ray, a CD, a ROM, a PROM, an EPROM,an EEPROM or a FLASH memory, having electronically readable controlsignals stored thereon, which cooperate (or are capable of cooperating)with a programmable computer system such that the respective method isperformed. Therefore, the digital storage medium may be computerreadable.

Some embodiments according to the invention comprise a data carrierhaving electronically readable control signals, which are capable ofcooperating with a programmable computer system, such that one of themethods described herein is performed.

Generally, embodiments of the present invention can be implemented as acomputer program product with a program code, the program code beingoperative for performing one of the methods when the computer programproduct runs on a computer. The program code may for example be storedon a machine readable carrier.

Other embodiments comprise the computer program for performing one ofthe methods described herein, stored on a machine readable carrier.

In other words, an embodiment of the inventive method is, therefore, acomputer program having a program code for performing one of the methodsdescribed herein, when the computer program runs on a computer.

A further embodiment of the inventive methods is, therefore, a datacarrier (or a digital storage medium, or a computer-readable medium)comprising, recorded thereon, the computer program for performing one ofthe methods described herein. The data carrier, the digital storagemedium or the recorded medium are typically tangible and/ornon-transitionary.

A further embodiment of the inventive method is, therefore, a datastream or a sequence of signals representing the computer program forperforming one of the methods described herein. The data stream or thesequence of signals may for example be configured to be transferred viaa data communication connection, for example via the Internet.

A further embodiment comprises a processing means, for example acomputer, or a programmable logic device, configured to or adapted toperform one of the methods described herein.

A further embodiment comprises a computer having installed thereon thecomputer program for performing one of the methods described herein.

In some embodiments, a programmable logic device (for example a fieldprogrammable gate array) may be used to perform some or all of thefunctionalities of the methods described herein. In some embodiments, afield programmable gate array may cooperate with a microprocessor inorder to perform one of the methods described herein. Generally, themethods are advantageously performed by any hardware apparatus.

The above described embodiments are merely illustrative for theprinciples of the present invention. It is understood that modificationsand variations of the arrangements and the details described herein willbe apparent to others skilled in the art. It is the intent, therefore,to be limited only by the scope of the impending patent claims and notby the specific details presented by way of description and explanationof the embodiments herein.

While this invention has been described in terms of several embodiments,there are alterations, permutations, and equivalents which fall withinthe scope of this invention. It should also be noted that there are manyalternative ways of implementing the methods and compositions of thepresent invention. It is therefore intended that the following appendedclaims be interpreted as including all such alterations, permutationsand equivalents as tall within the true spirit and scope of the presentinvention.

8. References

-   [BCC] C. Faller and F. Baumgarte, “Binaural Cue Coding—Part II:    Schemes and applications,” IEEE Trans. on Speech and Audio Proc.,    vol. 11, no. 6, November 2003-   [JSC] C. Faller, “Parametric Joint-Coding Audio Sources”, 120th AES    Convention, Paris, 2006, Preprint 6752-   [SAOC1] J. Herre, S. Disch, J. Hilpert, O. Hellmuth: “From SAC To    SAOC—Recent Developments in Parametric Coding of Spatial Audio”,    22nd Regional UK AES Conference, Cambridge, UK, April 2007-   [SAOC2] J. Engdegård, B. Resch, C. Falch, O. Hellmuth, J.    Hilpert, A. Hölzer, L. Terentiev, J. Breebaart, J. Koppens, E.    Schuijers and W. Oomen: “Spatial Audio Object Coding (SAOC)—The    Upcoming MPEG Standard on Parametric Object Based Audio Coding”,    124th AES Convention, Amsterdam 2008, Preprint 7377-   [SAOC] ISO/IEC, “MPEG audio technologies—Part 2: Spatial Audio    Object Coding (SAOC),” ISO/IEC JTC1/SC29/WG11 (MPEG) FCD 23003-2.

The invention claimed is:
 1. An audio signal decoder for providing anupmix signal representation based on a downmix signal representation andan object-related parametric information, and depending on a renderinginformation, the audio signal decoder comprising: an object parameterdeterminator configured to acquire inter-object-correlation values for aplurality of pairs of audio objects, wherein the object parameterdeterminator is configured to evaluate a bitstream signaling parameterin order to decide whether to evaluate individualinter-object-correlation bitstream parameter values, to acquireinter-object-correlation values for a plurality of pairs of relatedaudio objects, or to acquire inter-object-correlation values for theplurality of pairs of related audio objects using a commoninter-object-correlation bitstream parameter value; and a signalprocessor configured to acquire the upmix signal representation based onthe downmix signal representation and using the inter-object-correlationvalues for the plurality of pairs of related audio objects and therendering information; wherein the object-related parametric informationcomprises the bitstream signaling parameter and the individualinter-object-correlation bitstream parameter values or the commoninter-object-correlation bitstream parameter value; wherein the objectparameter determinator is configured to evaluate anobject-relationship-information, describing whether two audio objectsare related to each other; and wherein the object parameter determinatoris configured to selectively acquire inter-object-correlation values forpairs of audio objects, for which the object-relationship-informationindicates a relationship, using the common inter-object-correlationbitstream parameter value and to set inter-object-correlation values forpairs of audio objects, for which the object-relationship informationindicates no relationship, to a predefined value.
 2. The audio decoderaccording to claim 1, wherein the object parameter determinator isconfigured to evaluate the object-relationship information comprising aone-bit flag for each combination of different audio objects, whereinthe one-bit flag associated to a given combination of different audioobjects indicates whether the audio objects of the given combination arerelated or not.
 3. The audio decoder according to claim 1, wherein theobject parameter determinator is configured to set theinter-object-correlation value for all pairs of different related audioobjects to a common value defined by the common inter-object-correlationbitstream parameter value, or to a value derived from the common valuedefined by the common inter-object-correlation bitstream parametervalue.
 4. The audio decoder according to claim 1, wherein the objectparameter determinator comprises a bitstream parser configured to parsea bitstream representation of an audio content, to acquire the bitstreamsignaling parameter and the individual inter-object-correlationbitstream parameter values or the common inter-object-correlationbitstream parameter value.
 5. The audio decoder according to claim 1,wherein the audio signal decoder is configured to combine aninter-object-correlation value IOC_(i,j) associated with a pair ofrelated audio objects with an object level difference value OLD_(i)describing an object level of a first audio object of the pair ofrelated audio objects and with an object level difference value OLD_(j)describing an object level of a second audio object of the pair ofrelated audio objects, to acquire a covariance value e_(i,j) associatedwith the pair of related audio objects; wherein the audio decoder isconfigured to acquire an element e_(i,j) of a covariance matrixaccording to e_(i,j)=√{square root over (OLD_(i)OLD_(j))}IOC_(i,j). 6.The audio signal decoder according to claim 1, wherein the audio signaldecoder is configured to handle three or more audio objects; and whereinthe object parameter determinator is configured to provide aninter-object-correlation value for every pair of different audioobjects.
 7. The audio signal decoder according to claim 1, wherein theobject parameter determinator is configured to evaluate the bitstreamsignaling parameter, which is comprised in a configuration bitstreamportion, in order to decide whether to evaluate the individualinter-object-correlation bitstream parameter values to acquire theinter-object-correlation values for a plurality of pairs of relatedaudio objects, or to acquire the inter-object-correlation values for aplurality of pairs of related audio objects using the commoninter-object-correlation bitstream parameter value; and wherein theobject parameter determinator is configured to evaluate an objectrelationship information, which is comprised in the configurationbitstream portion, to determine whether two audio objects are related;and wherein the object parameter determinator is configured to evaluatea common inter-object-correlation bitstream parameter value, which iscomprised in a frame data bitstream portion for every frame of the audiocontent, if it is decided to acquire inter-object-correlation values fora plurality of pairs of related audio objects using a commoninter-object-correlation bitstream parameter value.
 8. A method forproviding an upmix signal representation based on a downmix signalrepresentation and an object-related parametric information and independence on a rendering information, the method comprising: acquiringinter-object-correlation values for a plurality of pairs of audioobjects, wherein a bitstream signaling parameter is evaluated in orderto decide whether to evaluate individual inter-object-correlationbitstream parameter values, to acquire inter-object-correlation valuesfor a plurality of pairs of related audio objects, or to acquireinter-object-correlation values for the plurality of pairs of relatedaudio objects using a common inter-object-correlation bitstreamparameter value; and acquiring the upmix signal representation based onthe downmix signal representation and using the inter-object-correlationvalues for the plurality of pairs of related audio objects and therendering information; wherein an object-relationship information,describing whether two audio objects are related to each other, isevaluated, and wherein the inter-object-correlation values areselectively acquired for pairs of audio objects, for which the objectrelationship-information indicates a relationship, using the commoninter-object-correlation bitstream parameter value, and wherein theinter-object-correlation values are set to a predefined value for pairsof audio objects, for which the object-relationship informationindicates no relationship; and wherein the object-related parametricinformation comprises the bitstream signaling parameter and theindividual inter-object-correlation bitstream parameter values or thecommon inter-object-correlation bitstream parameter value; wherein themethod is performed using a hardware apparatus, or using a computer, orusing a combination of a hardware apparatus and a computer.
 9. Anon-transitory storage medium having stored thereon a computer programfor performing the method for providing an upmix signal representationbased on a downmix signal representation and an object-relatedparametric information and in dependence on a rendering information, themethod comprising: acquiring inter-object-correlation values for aplurality of pairs of audio objects, wherein a bitstream signalingparameter is evaluated in order to decide whether to evaluate individualinter-object-correlation bitstream parameter values, to acquireinter-object-correlation values for a plurality of pairs of relatedaudio objects, or to acquire inter-object-correlation values for theplurality of pairs of related audio objects using a commoninter-object-correlation bitstream parameter value; and acquiring theupmix signal representation based on the downmix signal representationand using the inter-object-correlation values for the plurality of pairsof related audio objects and the rendering information; wherein anobject-relationship information, describing whether two audio objectsare related to each other, is evaluated, and wherein theinter-object-correlation values are selectively acquired for pairs ofaudio objects, for which the object relationship-information indicates arelationship, using the common inter-object-correlation bitstreamparameter value, and wherein the inter-object-correlation values are setto a predefined value for pairs of audio objects, for which theobject-relationship information indicates no relationship; and whereinthe object-related parametric information comprises the bitstreamsignaling parameter and the individual inter-object-correlationbitstream parameter values or the common inter-object-correlationbitstream parameter value, when the computer program runs on a computer.